A microphone includes a base and a microelectromechanical system (MEMS) die and an integrated circuit (IC) disposed on the base. The microphone also includes a cover mounted on the base and covering the MEMS die and the IC. The cover includes an indented region or an inwardly drawn region that define a top port through which acoustic energy can enter the microphone and be incident on the MEMS die. The microphone also includes a filtering material disposed on the top port on an outside surface of the cover and within the indented region or the inwardly drawn region. The filtering material provides resistance to ingression of solid particles or liquids into the microphone.

A method for forming a filter net on an MEMS sensor and an MEMS sensor are disclosed. The method comprises the following steps: disposing a dissociable adhesive tape on a base material, and forming a filter net on an adhesive surface of the dissociable adhesive tape; transferring the filter net on a film to form a self-adhesive coiled material; and transferring and adhering the filter net on the self-adhesive coiled material to collecting a hole of the MEMS sensor. The filter net formed by the method have fine and uniform meshes, and a yield is high. In addition, the method is suitable for large-scale and industrialized production.

A Micro Electro-Mechanical System (MEMS) device package includes a first circuit layer, a partition wall, a MEMS component, a second circuit layer and a polymeric dielectric layer. The partition wall is disposed over the first circuit layer. The MEMS component is disposed over the partition wall and electrically connected to the first circuit layer. The first circuit layer, the partition wall and the MEMS component enclose a space. The second circuit layer is disposed over and electrically connected to the first circuit layer. The polymeric dielectric layer is disposed between the first circuit layer and the second circuit layer.

A method for forming a filter net on an MEMS sensor and an MEMS sensor are disclosed. The method comprises the following steps: disposing a dissociable adhesive tape on a base material, and forming a filter net on an adhesive surface of the dissociable adhesive tape; transferring the filter net on a film to form a self-adhesive coiled material; and transferring and adhering the filter net on the self-adhesive coiled material to collecting a hole of the MEMS sensor. The filter net formed by the method have fine and uniform meshes, and a yield is high. In addition, the method is suitable for large-scale and industrialized production.

A fluid-control device comprises a stack of wafers in which flow components are provided as micro-electro-mechanical systemsMEMS. The flow components are selected from fluid-control components and/or fluid-monitor components. The fluid-control device has a first flow component that is encircled, in a main plane of the stack of wafers, by a second flow component.

In embodiments, a package assembly may include an application-specific integrated circuit (ASIC) and a microelectromechanical system (MEMS) having an active side and an inactive side. In embodiments, the MEMS may be coupled directly to the ASIC by way of one or more interconnects. The MEMS, ASIC, and one or more interconnects may define or form a cavity such that the active portion of the MEMS is within the cavity. In some embodiments, the package assembly may include a plurality of MEMS coupled directly to the ASIC by way of a plurality of one or more interconnects. Other embodiments may be described and/or claimed.

A package includes a support structure having an electrically insulating material, a microelectromechanical system (MEMS) component, a cover structure having an electrically insulating material and mounted on the support structure for at least partially covering the MEMS component, and an electronic component embedded in one of the support structure and the cover structure. At least one of the support structure and the cover structure has or provides an electrically conductive contact structure.

In embodiments, a package assembly may include an application-specific integrated circuit (ASIC) and a microelectromechanical system (MEMS) having an active side and an inactive side. In embodiments, the MEMS may be coupled directly to the ASIC by way of one or more interconnects. The MEMS, ASIC, and one or more interconnects may define or form a cavity such that the active portion of the MEMS is within the cavity. In some embodiments, the package assembly may include a plurality of MEMS coupled directly to the ASIC by way of a plurality of one or more interconnects. Other embodiments may be described and/or claimed.

A hole plate and a MEMS microphone arrangement are disclosed. In an embodiment a hole plate includes a substrate with a first main surface, a second main surface, and a lateral surface and a perforation structure formed within the substrate, the perforation structure having a plurality of through-holes through the substrate, wherein the through-holes and the lateral surface are a result of a simultaneous dry etching step.

A semiconductor device includes: a substrate; a transduction microstructure integrated in the substrate; a cap joined to the substrate and having a first face adjacent to the substrate and a second, outer, face; and a channel extending through the cap from the second face to the first face and communicating with the transduction microstructure. A protective membrane made of porous polycrystalline silicon permeable to aeriform substances is set across the channel.